Telemetric control system



I Novilo, 1942. J u s 7 2,301,897

TVELEMETRIG CONTROL SYSTEM Filed Nov. 25, .1958 s Sheets-Sheet} e p g Y I)" grg l7 4/ 7 l4 I 5 If 4 v I 4 u f I312 I 16 v Snventor FIG. 2 JOHN F. LUHRS Nov. 10, 1942. I J. F. LUHRS TELEMETRIC CONTROL SYSTEM 7 s Sheets-Sheet 2 Filed Nov. 25, 1938 FIG.

FIG. 4

Fug. 6

r o t n e D n 3 JOHN F. LUHRS (Ittomeg N 10, 1942 J. F. LUHRS I TELEMETRIC CONTROL SYSTEM Filed Nov 25. 195B :5 sheets-sheet z JOHN F. LUHRS Patented Nov. 10, 1942 TELEMETRIC ooN'raoL SYSTEM John F. Luhrs, Cleveland Heights, Ohio, assignor to Bailey Meter Company, a corporation of Delaware Application November 25, 1938, Serial No. 242,251

11 Claims.

This invention relates to telemetric control systems wherein a receiving means is positioned by one or more transmitting means, each responsive to the magnitude of a variable, such as position, pressure, temperature, rate of flow. More particularly my invention relates to the impulse class of telemeters wherein a receiving means is periodically positioned for a time duration corresponding to the difference in magnitude of a plurality of variables.

'Ielemetric systems are well known in the art wherein a first transmitting means periodically originates electric signals of a time duration corresponding to a first variable, a second transmitting means simultaneously ori hates electric signals of a time duration corresponding to a second variable and a receiver means jointly responsive to the signals is selectively positioned in one direction orthe other by an amount corresponding to the difference in time duration of the signals. Usually theireceiving means is used to control one or the other of the variables to maintain the signals 0 qual time duration, and hence to maintain a p r%etermined relation between the variables. S'ch systems are shown and described, for example, in U. S. Patents 2,046,676 and 2,015,968 to W. E. Dueringer and J. D. Ryder respectively.

An inherent characteristic of such systems is that upon a temporary fault in one of the transvariable may be the fiow of fuel to a furnace, the. second variable the flow of air thereto, and the latter controlled by the receiving means to maintain a predetermined ratio between fuel and air. Upon failure of one or the other of the signals the receiving means would be positioned an excessive amount, so that a violent change in \air flow would occur, causing an acute deficiency or great excess of air for combustion.

nitude of the several variables and that upon a temporary fault in one of the transmitting means the receiving means will remain stationary until My invention while relating to the same general class of telemetric systems difiers therefrom in thatthe several transmitting means jointly ,produce but a single periodic signal of a time normal operationof the transmitting means is' restored.

In the drawings:

Fig. 1 illustrates a transmitting mechanism.

Fig. 2 illustrates a combination transmitting and receiving mechanism which may be used in conjunction with the transmitting mechanism shown in Fig. 1.

Fig. 3 is a diagram showing the iring in and between the mechanisms shown in Figs. 1 and 2.

Fig. 4 is a modified form of the wiring shown in Fig. 3.

Figs. 5 and 6 illustrate modifications which may be incorporated in Figs. 3 and 4.

Fig. '7 illustrates a modification of my invention which may be used with the transmitting means shown in Figs. 1 and 2.

Fig. 8 illustrates a further modified form of my invention.

Fig. 9 is a sectional elevation view along the lines 9-9 of Fig. 8 in the direction of the arrows.

Fig. 10 is a fragmentary view to larger size of a part of the mechanism shown in Fig. 8.

Fig.11 illustrates a further modified form of my invention.

Fig. 1 illustrates the basic transmitting mech anism I employ for originating signals, while Fig. 2 illustrates a transmitting means employing the same basic mechanism as shown in Fig. 1, and incorporated therewith a receiving means which is Jointly responsive to both the transmitting means shown in Figs. 1 and 2. For the sake of clarity I have not shown in Figs. 1 and 2 the electrical connections between the several mechanisms. Such connections are shown in Fig. 3 and in a modified form in Fig. 4. I will first describe my invention with reference to Figs. 1,

temperature, rate of flow, or it may be positioned manually. Regardless of the particular factor which is used to position the spindle 2 it will be observed as the description proceeds that it is the position of the pointer l which in'part det'eras the second variable.

mines the signals transi. itted to the receiving means, and that therefore this position may be defined as the first variable.

The pointer carries a rearwardly extending arm 6 pivotally connected by a link 1 to a lever 8 fulcrumed on a stationary shaft 9. It will be observed that when the pointer is adjacent the lowest graduation on the scale 5 the lever 8 is at its extreme clockwise position and as the pointer. I is positioned upwardly the lever 8 is positioned in a counterclockwise direction a corresponding amount.

Pivoted on the shaft 9 is a contact member l having a laterally extending arm carrying a contact l2 normally resting on a cooperating contact 3 carried by the lever 8. Also pivoted on the shaft 9 is a follower arm l4 carrying a roller |5 normally in contact with a revoluble cam Hi. When in operation, the cam I6 is continuously rotated by a self-starting synchronous motor |1 so that the follower arm I4 is periodically or cyclically reciprocated between definite limits which are slightly greater than the limits of travel of the lever 8.

The follower arm |4 carries a transversely extending platform |8 on which is a contact |9 disposed to engage a contact carried by the member Hi. It will be noted that during the upward travel of the follower l4 the contact I9 will engage the contact 20 for a time duration corresponding to the position of the pointer l. Simul taneously with the engagement of the contacts l9 and 20 contacts |2 and I3 will disengage, and remain disengaged while the former are engaged.

Referring now particularly to Fig. 2, it will be observed that the same basic transmitting mechanism is shown. That is to say there is a pointer 2| and a cooperating index 2 IA. The position of the pointer relative to the index may be taken The pointer is secured to a spindle 22 and connected to a lever 23 pivotally mounted on a stationary shaft 24. Also pivotally mounted on the shaft 24 is a contact member 25 having a laterally extending arm 26 carrying a contact 21 normally resting on a contact 28 carried by the lever 23. The shaft 24 also piv otally supports a follower 29 carrying a roller 30 normally engaging a cam 3| continuously rotated by a self-starting synchronous motor 32. Carried by the follower 29 is a platform 29A on which is disposed a contact 33 adapted to engage a contact 34 on the member 25.

In operation the cams I8 and 3| rotate at identical speeds by virtue of the synchronous driving motors l1 and 32. The cams are also maintained (by means hereinafter-to be described) in exact predetermined phase relationship. That is to say, the speed of the motor 32 is temporarily varied at predetermined time intervals if the roller 30 does not engage the point on the cam 3| corresponding to the point engaged by the roller l5 on the cam IS. The followers l4 and 29 are therefore reciprocated in unison, and if the position of the pointer agrees with the position of the pointer 2| contacts l9 and 20 will engage simultaneously with the engagement of contacts 33 and 34. If such agreement does not exist, then engagement of the said sets of contacts will occur in sequence, the time difference being dependent upon the relative positions of the pointers I and 2|. Simultaneously disengagement of contacts |2-| 3 and 21-28 will occur in sequence, the time difference again being dependent upon the relative positions of the pointers and 2 The receiving means, as shown in Fig. 2, comprises a reversing motor 35 having an energizing field 38, opposed pole windings 31 and 38, and an output arm 39 connected to the rotor of the motor through a suitable gear reduction 39A. It will be understood by those familiar with the art that when the winding 31 is short circuited the output arm 39 will angularly move in one direction, when the winding 38 is short circuited the arm will move in opposite direction, and when both windings are concurrently short circuited or open circuited the arm remains stationary. By circuit arrangements, hereinafter to be described in detail, one or the other of the windings is periodically energized for a time duration corresponding to the difference in magnitude of the first and second variables.

. In the mechanism shown in Fig. 2 the arm 35 is shown mechanically coupled through a link 39B to a depending arm 40 of the lever 23, and therefore by direct connection determines the position of the pointer 2|, or in other words. the magnitude of the second variable. In some cases (as described with reference to Fig. 7) the link 39B may be eliminated and the coupling made by other means, so that while the receiving means controls the magnitude of the second variable, there is no direct mechanical connection between the receiving means and one or the other of the transmitting means. In still other cases it may be desirable to have no connection, either direct or indirect, between the receiving means and one or the other of the transmitting means.

In the arrangement shown in Figs. 1, 2 and 3 the operation of the motor 35 is such as to maintain correspondence between the position of the pointers and 2|. Referring now particularly to Fig. 3, I have shown the contacts |2-|3, l9-20, in the first transmitter (Fig. 1) and contacts 21-28, 33-34 in the second transmitter (Fig. 2) in diagrammatic form and the circuit connections therebetween. The system may be energized from any suitable source, such as indicated at 4|, one side of which forms a neutral 42 to the contacts l9, I2, 33, and 21. Contact 20 is connected by a wire 43 to the winding 31 of the motor 35. Contact 34 is connected to the opposed winding 38 by a wire 44. Contacts l3 and 28 are connected by wires 45 and 48 to the common 41 of the motor 35.

It will be observed that with contacts l9-28 and 33-34 disengaged, windings 31 and 38 are cleenergized. Upon engagement of contacts |9-20 winding 31 is short circuited, and upon engagement of contacts 33-34 winding 38 is short circuited. Assuming that contacts I9-20 engage first, it will further be observed that the winding 31 will be energized only until contacts 33-34 engage by virtue of the simultaneous disengagement of contacts 21-28. Likewise if contacts 33-34 engage first, winding 38 will be energized only until engagement of contacts l9-2Il and simultaneous disengagement of contacts l2-l3. If both sets of contacts simultaneously engage, both windings will remain deenergized. It is therefore apparent that the windings of the receiving means 35 will be selectively periodically energized for time increments dependent upon the relative magnitudes of the first and second variables.

The means I employ for maintaining the cams l8 and 3| in exact phase relation comprise means for periodically stopping the motor 32 if correct phase relationship does not exist unt l correct relationship is restored. The motor 32 is normally energized from source 4|, lead 50, and

return lead through normally closed contacts mally open contacts 56 and 57. Contacts 56-5| are closedby the follower l4 riding up on a lip 58 of the cam Hi. If proper phase relationship does not exist between cams I6 and 3| then the aforesaid sequential operation of contacts -52-53 and 56-51 will not occur, causing periodic de- 4 energization of the motor 32 until proper phase relationship is restored.

To facilitate such double usage of the cams l6 and 3|, and further to permit a different shape of the falling section of the'cams I show connected in the common 41 of the motor 35 a mercury switch 60 for maintaining the common open during the portion of each revolut on of the cam 3| designated as B. As shown in Fig. 2, the mercury switch 60 is arranged to be actuated by the follower 29 so that during the rising section A of the cam 3| the common is closed and during the remaining section .B' the common is open so that regardless of the engagement or disengagement of contacts |9-2ll, |2-|3, 2|-2B. and 33-34 the motor 35 remains stationary. If cams l6 and 3| are in proper phase relationship then sections A, B of cam IE will correspond with sections A. B of cam 3|. r

In Fi 3 I show the energizing field 35 of the motor 35 directly connected to the source 4| through leads and 1|. In Fig. 4 I show a modified form of my invention where n the co Referring to Fig. 5, I therein show connected in series circuit arrangement with the motor 32 2 solenoid coil 80 and an armature 8| carrying a contact plate 82. When the contact plate is in open position, as shown, an alarm device herein shown as a bell 83 is open circuited. Upon failure of current to the motor 32 the solenoid 80 is deenergized, permitting the contact plate 82 to fall, thereby energizing the alarm device 83.

In Fig. 6 the contact plate 82 is shown arranged to open circuit the entire system, so that upon deenergization of motor '32 the entire system will be rendered inoperative. In both the modifications shown in Figs. 5 and 6 the arma ture 8| may be arranged to drop out of the magnetic field formed by the solenoid 80, so that upon restoration of the current to the motor 32 it is necessary to reset it by hand, or it may be arranged so that upon reenergization it automatically is restored to its normal position.

In Fig, 7 I have shown a modified form of my invention wherein the receiving means 35 is in-' directly coupled to the indicator 2 i. As a specific embodiment I have shown a modification wherein the receiving means is arranged to regulate the rate of flow of fluid through a conduit 90 by positioning a valve 9| disposed therein. The

arrangement between the two transmitting means "and the receiving means 35 may be as shown in field 36 throu h a lead 12; whereas contacts 2'|'28 are connected to the same side of the field through a lead 13. If the circuit arran ement of Fig. 4 is used the operation is exactly the same as that described with reference to Figs. 1. 2

and 3. Assuming for example that contacts iii-20 engage first, opposed winding 31 will be energized by virtue of the fact that the ener izthe simultaneous opening of contacts 21 -28.

Conversely, if contacts 33-34 close first, windin 38 will be energized, but only until contacts |92|| close and corresponding opening of contacts |2-|3. It is thus evident that as with the circuit arrangement shown in Fig. 3 the arrangement shown in Fig. 4 will provide forthe periodic selective energization of the opposed winding 31 or 38 for a time increment corresponding to the diiference in magnitude of the two variables.

The repliasing operation carried on subsequent to loss of proper phase relationship between cams l6 and 3| may produce errors in the operation of the receiving means, which while of a minor character may cause undesirable changes in one or the other of the variables. Suitable means are shown in Figs. 5 and 6 which may be incorporated in either of the circuit arrangements shown in Figs. 3 and 4 for sounding an alarm or shutting down the entire system until manually reset.

either Figs. 3 or 4. If desired,to maintain the rate of fluid flow through the conduit at some predetermined value, then the pointer I would be set at a position corresponding to that rate. Thereafter the receiving means would periodically position the valve 9| by an amount corresponding to the difference between the desired rate (as determined by the position of the pointer I) and the actual rate (as determined by the position of the pointer 2|) and in a sense to bring the actual rate into correspondence with the desired rate.

In other applications it may be desired to maintain the rate of fluid fiow through the conduit 90 in predetermined ratio to the rate of fluid flow through a second "conduit. In such applications I may cause the'pointer to be positioned by a flow meter, such as shown' in 93, so

fictitious v that it is moved in correspondence with the rate of fluid flow through the second conduit. With this arrangement the receiving means will again vary the position of the valve 9| to maintain the rate of flow through the conduit 90 equal to or in desired proportion to the rate of fluid flow through the second conduit. It will be obseryed that in general the system disclosed in Fig. 7 operates to'maintain a predetermined ratio between a first or independent variable and a second or dependent variable. I

In Figs. 8, 9 and 10 I show a further modified form of my invention somewhat different as to mechanical arrangement than the embodiments heretofore described, but embodying the same basic principles. Referring to the drawings, there is shown a movable pointer 00 which may be horizontally positioned along an anvil IDDA by a variable responsive means, such as a galvanor eter, flow meter, ammeter, etc. Two feelers |0| and H12 are adapted to be reciprocated about a bearing I05 by a cam I03 continuously rotated by a motor I04. Periodically the feeler I02 is brought into engagement with the pointer I for an increment of time corresponding to the distance of the pointer from the left-hand edge of the anvil IO0A as viewed in the drawings. Concurrently the feeler ml is brought into engagement with the pointer I00 for an increment of time corresponding inversely to the distance of the pointer from the left-hand edge of the anvil IIJOA. The feelers IOI and I02 are so shaped and relatively disposed that when the pointer I00 is in the mid point of the anvil IO0A, or What is commonly termed the neutral position, their time of engagement therewith is identical. My invention, in general, contemplates periodically selectively energizing a reversible receiving means, such as diagrammatically indicated at I06, for a time increment corresponding to the difference in time length of engagement between the pointer I00 and feelers IOI and I02.

To periodically reciprocate the feelers IOI and I02 a cam follower I0! is provided, also pivoted on the bearing I05. Cam follower I01 carries contacts I08 and I09 which engage, through a portion of each reciprocation, contact assemblies H0 and III carried by the feelers IM and I02 respectively. The contact assemblies H0 and III also serve as pickups for the feelers, so that the latter are reciprocated from one limit, determined by the rise of the cam I03, to another limit, determined by the position of the pointer I00. It is thus seen that the position of the pointer I00 will determine the relati e time of closure during each cycle of contacts I09-H0 and I 08--I I I.

The receiving means I06 is shown as a motor having opposed'pole windings H2, H3 and an energizing field H4. The circuit for the opposed winding I I2 may be traced as follows: From common H5 to contact I09, cooperating contact H6, contact I I! to lead I I8. The circuit for the winding H3 may be traced as follows: From common H5 to contact I08, cooperating contact H9, contact I tolead I2I.

Referring now particularly to Figs. 9 and 10, it will be noted that the contact assemblies I I0 and III comprise insulating bushings I22 and I23 which are carried by the feelers IOI and I02 respectively, and con-conducting members I24 and I25 movable in the bushings between limits. Normally, the members I24 and I25 are disposed by gravity, as shown, with contacts H1 and I20 closed. When, however, contact I08 engages contact H9, contact I I! is broken, and when contact I09 engages contact II-6, contact I20 is broken.

In operation, with the follower I01 in the position as shown windings H2 and H3 of the motor I06 are both open circuited inasmuch as contacts I09 and I08 are disengaged from contacts H6 and H9 respectively. When the follower I01 moves upwardly and assuming contact I08 engages contact I I9 first, winding H2 will be short circuited, but only until contact I09 engages contact H6 when by virtue of contact I20 breaking winding I I3 will be open circuited. Engagement of contacts I09 and H6 will not effect short circuiting of winding II 2 inasmuch as contact H! was broken by engagement of contacts I 08 and H9. If cont-acts I09II6 and I08--II9 simultaneously engage, then neither winding I I2 or H3 will be short circuited, due to the simultaneous opening of contacts I! and I20.

I may provide in the common H5 a suitablemercury switch I arranged to be actuated by the motor I04 so that only during the rising section of the cam I03 can the windings H2 and H3 be short circuited by closure of contacts I09-I I6 or I08I I9.

In Fig. 11 I show apparatus similar to that disclosed in Fig. 8 illustrating a further modified form of my invention. In this modification feelers IOI and I02 carry contacts I3I and I32 respectively disposed to be engaged by contacts I09A and I08A carried by a non-conducting bushing I IOA on the cam follower I01. The common for the motor I06 includes the mercury switch I30 in lead I33, pointer I00, and the feelers IM and I02. So long as the pointer I00 engages either or both feelers IN and I02 contacts I3I and I32 will be electrically connected to the lead I33. Upon both feelers being disengaged from the pointer I00, then neither winding H2 or winding H3 can be short circuited by closure of contacts I09A-l3l or I06A-I32 respectively as lead I33 is electrically disconnected from contacts I3I and I32.

In operation, assuming contact I09A to engage the contact I3I first, the winding H2 will be energized until contact I08A engages contact I32, thereby causing feeler I02 to be lifted from the pointer I00, and thus opening the common of the windings H2 and H3. Similarly, if contact I08A engages contact I32 first, winding H3 of motor I06 will be energized, but only until contact I09A engages contact I3I lifting feeler IDI from the pointer I00 and breaking the common.

It will be observed that the time duration of the short circuiting of either winding H2 or H3 is dependent upon the difference in time duration of closure of' contacts I09A--I3I and I08A-I32, and that when these contacts simultaneously engage neither winding I I2 or I I3 is energized.

In the embodiments of my invention shown in Figs. 8 and 11, it will be observed that if contacts I08, I09 and I08A, I09A merely served to engage the contacts carried by the feelers MI and I02, the windings H2 and H3 would be continuously energized for the time duration of such engagement. In the event of contact failure the motor I06 would rotate in one direction for the entire time duration of 'closure of the other contact. Such rotation would not correspondto the position of the pointer I00. With my invention the opposed windings of the motor I06 are energized only for the difference in time duration of the closure of the contacts, and upon failure of either contact the motor will remain stationary until the fault is remedied.

While I have not felt it necessary to illustrate the function of the motor I06, it will be evident to those skilled in the art that it may be used to rebalance a potentiometer system determining in part the position of the pointer I00, or that it may be used to control a variable, the magnitude of which, or departure from desired magnitude, is indicated by the position of the pointer I00.

The foregoing description and the drawings serve to emphasize that my invention can be found in various forms without change in substance. It should be understood, therefore, that the description and drawings merely serve to illustrate representative applications of my invention and are not to be considered as defining the scope thereof.

What I claim as new, and desire to secure by Letters Patent of the United States, is:

- ting means for cyclically closing the circuit of in one direction and a second winding which when energized produces movement of the receiving means in opposite direction, a first electric circuit for controlling energization of the first winding and a second electric circuit for controlling energization of the second winding, a first transmitting means including means for closing said first circuit and means operated electrically independently oi. said last named means for simultaneously opening said second circuit, and a second transmitting means including means for closing said second circuit and means operated electrically independently of said last named means for simultaneously opening said' first circuit so that if either of the said means for closing the first or second circuits electrically fails neither of said windings is energized for the duration of said failure. v

2. Telemetric apparatus comprising a receiving means having opposed windings, a first transmitone of the windings for a time duration corresponding to the magnitude of a first variable, a

second transmitting means operated in synchronism with the first transmitting means for cyclically'closing the circuit of the other of the windings for a time duration corresponding to the magnitude of a second variable, and mechanically operated means under the joint control of both the transmitting means for inhibiting operation of the receiving means iorthe duration of the circuit closure of shorter time duration.

3. Telemetric apparatus comprising a motor having opposed pole windings and an energizing winding, a first transmitting means for cyclically short circuiting one of the opposed pole'windings. for a time duration corresponding to the magnitude of a first variable, a second transmitting means operated in synchronism with the first transmitting means for cyclically short circuiting the other opposed pole winding for a time duration corresponding to the magnitude'of a second variable, and means under the joint control of both said transmitting means for deenergizing -the energizing winding of the receiving means during the time when both said opposed pole windings are short circuited.

4. Telemetric apparatus for cyclically producing an electric impulsecorresponding in time duration to the difieren e in magnitude or two variables and receiver eans responsive to said impulses, comprising a separate transmitting means for each variable, a separate means responsive to each variable, means including a cyclically operable'means in each of said transmitting means cooperating with the said responsive means for originating an electricimpulse at a point in each cycle corresponding to the magnitude of the variable, means in each transmitting means simultaneously actuated by said responsive means and said cyclically operable means independently of the means for originating an electric impulse for positively terminating member, and means actuated by said member and said cyclically operable means independently of said means for originating energization of a selected one of said windings for terminating energization of the other of said windings so that if saidrneans for originating energization of a selected one of saidwindings electrically fails energization of the other of said windings for the duration of the failure is inhibited.

6. Telemetric apparatus for cyclically producing an electric impulse corresponding in time duration to the' amount of departure of two movable members from positions of correspondence' and receiver means responsive to said impulses, comprising in combination, two movable members, a separate transmitting means associated with each of said members, cyclically operable means in each of said transmitting means cooperating with the associated member for originating an electric impulse at a point in each cycle corresponding to the position of the mem-,

ber, and means in each transmitting means mechanically actuated by the movable member and the cyclically operable means for terminating at a point in each cycle determined by the position of the member the impulse originated by the other transmitting means so that if either of said transmitting eans fails to originate an electric impulse op ration of said receiver means is in, hibited for 'the'duration oi the failure.

7. In a telemetric control system, receiving means having a first winding which when energized produces movement 01! the receiving means in one direction, and a second--winding which when energized produces movement oi-the receiv-- mg means in opposite direction, a first electric circuit for controlling energization of the first the impulse originated by the other transmitting 85 means so that upon Iailure of either of said means for originating an electric impulse no 1m j pulse is transmitted to said receiver means for the duration of the failure.

5. Telemetric apparatus comprising a receiving means having opposed windings and transmitting means for cyclically producing an electric impulse of a time duration corresponding to the diflerence in magnitude 01' two variables and including means for selectively energizing winding and a second electric circuit for controlling energization of the econd winding, two

switches in each of the circui s, a first transmitting means which when operated closes a switch in said first circuit and simultaneously electri- I cally independent of the closure of said last name switch opens a switch in said second circuit, and a second transmititng means which when operated closes a switch in the second circuit and simultaneously electrically independent of the closure of said last named switch opens a switch in the first circuit, so that one or the other of the windings is energized solely for a time duration corresponding to the lapse of time between operation of the transmitting means and a selected one of the windings is energized as determined by which of the transmitting means is first operated.

8. Telemetric apparatus for cyclically producing an electric impulse corresponding in time [0 duration to the amount of departure of two movable members from positions of correspondence and receiver means responsive to said impulses,

comprising in combinationftwo movable members, a separate transmitting means associate with each movable member, means including a cyclically operable means in each of said transmitting means cooperating with the associated movable member for originating an electric impulse at a point in each cycle corresponding to the position of the movable member, means in each transmitting means simultaneously actuated by the movable member, and cyclically operable means independently of the means for originating an electric impulse for positively terminating the impulse originated by the other transmitting means so that upon failure of either of said means for originating an electric impulse no impulse is transmitted to said receiver means for the duration of the failure.

9. A telemetric system, comprising in combination, receiving means comprising electromagnetic means having a pair of opposed windings, two transmitting means for controlling the energization of said windings, each of said transmitting means comprising; a shaft, a transmitting arm angularly positionable about said shaft, a contact member pivotally mounted on said shaft and normally resting on said transmitting arm, a cam having a rising and a falling section, a follower member having one end pivoted on said shaft and the other engaging said cam, a motor for rotating said cam to periodically reciprocate said follower member through a predetermined cyclic course and carry said contact member through a portion of said cyclic course determined by the position of said transmitting arm, a first contact means mechanically operated by engagement of said follower member with said contact member to closed position, and a second contact means mechanically operated by disengagement of said contact member from said transmitting arm to open position; a separate circuit for energizing each of said windings, one of said circuits including the first contact means of one of the transmitting means and the second contact means of the other transmitting means, and the other of said circuits including the first contact means of said other transmitting means and the second contact means of said one of said transmitting means.

10. In a telemetric control system, in combination, receiving means having opposed windings, a first member and a second member, one of said members being adjustable relative to the other, a first transmitting means for cyclically closing the circuit of one of the windings for a time duration corresponding to the position of said first member, a second transmitting means operated in synchronism with the first transmitting means for cyclically closing the circuit of the other of the windings for a time duration corresponding to the position of said second member, and mechanically operated means under the joint control of both the transmitting means for inhibiting operation of the receiving means for the duration of the circuit closure of shorter time duration. I

11. In a telemetric control system, in combination, receiving means comprising a motor having opposed pole windings and an energizing winding, a first adjustable transmitting means for cyclically short circuiting one of the opposed pole windings for a variable time duration, a second adjustable transmitting means operated in synchronism with the first transmitting means for cyclically short circuiting the other opposed pole winding for a variable time duration, and means under the joint control of both said transmitting means for deenergizing the energizing winding of the receiving means during the time when both said opposed pole windings are short circuited.

JOHN F. LUHRS. 

